regulating gene expression goal is controlling proteins how many? where? how active?
DESCRIPTION
Regulating gene expression Goal is controlling Proteins How many? Where? How active? 8 levels (two not shown are mRNA localization & prot degradation). Transcription in Eukaryotes Pol I: only makes 45S-rRNA precursor 50 % of total RNA synthesis insensitive to -aminitin - PowerPoint PPT PresentationTRANSCRIPT
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Regulating gene expressionGoal is controlling Proteins•How many?•Where?•How active?8 levels (two notshown are mRNAlocalization & protdegradation)
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Transcription in EukaryotesPol I: only makes 45S-rRNA precursor• 50 % of total RNA synthesis• insensitive to -aminitin•Mg2+ cofactor•Regulated @ initiation frequency
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RNA Polymerase III makes ribosomal 5S and tRNA (+ some snRNA & scRNA)>100 different kinds of genes ~10% of all RNA synthesisCofactor = Mn2+ cf Mg2+
sensitive to high [-aminitin]
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RNA Polymerase II
makes mRNA (actually hnRNA), some snRNA and scRNA
• ~ 30,000 different gene models
• 20-40% of all RNA synthesis
• very sensitive to -aminitin
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Initiation of transcription by Pol II
Basal transcription
1) TFIID binds TATAA box
2) TFIIA and TFIIB bind to
TFIID/DNA
3) Complex recruits Pol II
4) Still must recruit
TFIIE & TFIIH to
form initiation complex
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Initiation of transcription by Pol IIBasal transcription1) Once assemble initiation complex must start Pol II2) Kinase CTD
negative charge gets it started
3) Exchange initiation for elongation factors4) Continues untilhits terminator
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Initiation of transcription by Pol IIBasal transcription1) Once assemble initiation complex must start Pol II2) Kinase CTD
negative charge gets it started
3) RNA pol II is pausedon many promoters!• even of genes thataren’t expressed!•Early elongation is also regulated!
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Initiation of transcription by Pol IIRNA pol II is paused on many promoters!• even of genes that aren’t expressed! (low [mRNA])•Early elongation is also •regulated!• PTEFb kinases CTD to stimulate processivity &processing
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Initiation of transcription by Pol IIRNA pol II is paused on many promoters!• even of genes that aren’t expressed! (low [mRNA])•Early elongation is also •regulated!• PTEFb kinases CTD to stimulate processivity &processing• Many genes have short transcripts
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Initiation of transcription by Pol IIRNA pol II is paused on many promoters!• even of genes that aren’t expressed! (low [mRNA])•Early elongation is also •regulated!• PTEFb kinases CTD to stimulate processivity &processing• Many genes have short transcripts•Yet another new level of control!
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TranscriptionTemplate strand determines next basePositioned by H-bondsuntil RNA polymeraselinks 5’ P to 3’ OH in front
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TranscriptionTemplate strand determines next basePositioned by H-bondsuntil RNA polymeraselinks 5’ P to 3’ OH in frontEnergy comes from hydrolysisof 2 Pi
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TranscriptionNTP enters E site & rotates into A site
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TranscriptionNTP enters E site & rotates into A siteSpecificity comes from trigger loop
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TranscriptionSpecificity comes from trigger loopMobile motif that swings into position & triggers catalysis
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TranscriptionSpecificity comes from trigger loopMobile motif that swings into position & triggers catalysisRelease of PPi triggers translocation
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TranscriptionProofreading: when it makes a mistake it removes ~ 5 bases & tries again
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Activated transcription by Pol IIStudied by mutating promoters for reporter genes
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Activated transcription by Pol IIStudied by mutating promoters for reporter genesRequires transcription factors and changes in chromatin
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Activated transcription by Pol IIenhancers are sequences 5’ to TATAA
transcriptional activators bind them• have distinct DNA binding and activation domains
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Activated transcription by Pol IIenhancers are sequences 5’ to TATAA
transcriptional activators bind them• have distinct DNA binding and activation domains
• activation domain interacts with mediator• helps assemble initiation complex on TATAA
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Activated transcription by Pol IIenhancers are sequences 5’ to TATAA
transcriptional activators bind them• have distinct DNA binding and activation domains
• activation domain interacts with mediator• helps assemble initiation complex on TATAA•Recently identified “activating RNA”: bind enhancers & mediator
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Activated transcription by Pol II•Other lncRNA “promote transcriptional poising” in yeasthttp://www.plosbiology.org/article/info%3Adoi%2F10.1371%2Fjournal.pbio.1001715•lncRNA displacesglucose-responsiverepressors & co-repressors from genesfor galactose catabolism
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Activated transcription by Pol II•Other lncRNA “promote transcriptional poising” in yeasthttp://www.plosbiology.org/article/info%3Adoi%2F10.1371%2Fjournal.pbio.1001715•lncRNA displacesglucose-responsiverepressors & co-repressors from genesfor galactose catabolism•Speeds induction ofGAL genes
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Euk gene regulationInitiating transcription is 1st & most important controlMost genes are condensedonly express needed genesnot enough room in nucleus toaccess all genes at same time!must find & decompress gene
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First “remodel” chromatin:• some proteins reposition nucleosomes • others acetylate histones• Neutralizes +ve charge• makes them release DNA
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Epigenetics•heritable chromatin modifications are associated with activated & repressed genes
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EpigeneticsChIP-chip & ChiP-seq data for whole genomes yieldcomplex picture: 17 mods are associated with active genes in CD-4 T cells
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Generating methylated DNASi RNA are key: generated from antisense or foldbackRNA
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Generating methylated DNASi RNA are from antisense or foldback RNAPrimary 24 nt siRNA are generated by DCL3
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Generating methylated DNASi RNA are from antisense or foldback RNAPrimary 24 nt siRNA are generated by DCL3: somehow polIV is attracted to make more RNA
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Generating methylated DNASi RNA are from antisense or foldback RNAPrimary 24 nt siRNA are generated by DCL3: somehow polIV is attracted to make more RNARDR2 makes bottom strand
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Generating methylated DNASi RNA are from antisense or foldback RNAPrimary 24 nt siRNA are generated by DCL3: somehow polIV is attracted to make more RNARDR2 makes bottom strandDCL3 cuts dsRNA into 24nt2˚ siRNA
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Generating methylated DNASi RNA are from antisense or foldback RNAPrimary 24 nt siRNA are generated by DCL3: somehow polIV is attracted to make more RNARDR2 makes bottom strandDCL3 cuts dsRNA into 24nt2˚ siRNAAmplifies signal!-> extendsMethylated region
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Generating methylated DNASi RNA are from antisense or foldback RNAPrimary 24 nt siRNA are generated by DCL3: somehow polIV is attracted to make more RNARDR2 makes bottom strandDCL3 cuts dsRNA into 24nt2˚ siRNAAmplifies signal!-> extendsMethylated regionThese guide “silencingComplex” to target site(includes Cytosine & H3K9 Methyltransferases)
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mRNA PROCESSINGPrimary transcript is hnRNAundergoes 3 processing reactions before export to cytosolAll three are coordinated with transcription & affect gene expression: enzymes piggy-back on POLII
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mRNA PROCESSINGPrimary transcript is hnRNAundergoes 3 processing reactions before export to cytosol1) Capping addition of 7-methyl G to 5’ end
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mRNA PROCESSINGPrimary transcript is hnRNAundergoes 3 processing reactions before export to cytosol1) Capping addition of 7-methyl G to 5’ end
identifies it as mRNA: needed for export & translation
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mRNA PROCESSINGPrimary transcript is hnRNAundergoes 3 processing reactions before export to cytosol1) Capping addition of 7-methyl G to 5’ end
identifies it as mRNA: needed for export & translationCatalyzed by CEC attached to POLII
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mRNA PROCESSING1) Capping2) Splicing: removal of intronsEvidence:• electron microscopy• sequence alignment
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Splicing: the spliceosome cycle
1) U1 snRNP (RNA/protein complex) binds 5’ splice site
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Splicing:The spliceosome cycle1) U1 snRNP binds 5’ splice site2) U2 snRNP binds “branchpoint”
-> displaces A at branchpoint
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Splicing:The spliceosome cycle1) U1 snRNP binds 5’ splice site2) U2 snRNP binds “branchpoint”
-> displaces A at branchpoint3) U4/U5/U6 complex binds intron
displace U1spliceosome has now assembled
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Splicing:RNA is cut at 5’ splice sitecut end is trans-esterified to branchpoint A
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Splicing:5) RNA is cut at 3’ splice site6) 5’ end of exon 2 is ligated to 3’ end of exon 17) everything disassembles -> “lariat intron” is degraded
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Splicing:The spliceosome cycle
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Splicing:
Some RNAs can self-splice!
role of snRNPs is to increase rate!
Why splice?
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Splicing:
Why splice?
1) Generate diversity
exons often encode protein domains
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Splicing:Why splice?
1) Generate diversityexons often encode protein domainsIntrons = larger target for insertions, recombination
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Why splice?
1) Generate diversity
>94% of human genes show alternate splicing
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Why splice?
1) Generate diversity
>94% of human genes show alternate splicing
same gene encodes
different protein
in different tissues
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Why splice?
1) Generate diversity
>94% of human genes show alternate splicing
same gene encodes
different protein
in different tissues
Stressed plants use
AS to make variant
stress-response
proteins
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Why splice?
1) Generate diversity
>94% of human genes show alternate splicing
same gene encodes
different protein
in different tissues
Stressed plants use
AS to make variant
Stress-response
proteins
Splice-regulator
proteins control AS:
regulated by cell-specific
expression and phosphorylation
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Splicing:
Why splice?
1) Generate diversity
2) Modulate gene expression
introns affect amount of mRNA produced
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mRNA Processing: RNA editing
Two types: C->U and A->I
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mRNA Processing: RNA editing
Two types: C->U and A->I
• Plant mito and cp use C -> U
•>300 different editing events have been detected in plant mitochondria: some create start & stop codons
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mRNA Processing: RNA editing
Two types: C->U and A->I
• Plant mito and cp use C -> U
•>300 different editing events have been detected in plant mitochondria: some create start & stop codons: way to prevent nucleus from stealing genes!
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mRNA Processing: RNA editingHuman intestines edit APOB mRNA C -> U to create a stop codon @ aa 2153 (APOB48) cf full-length APOB100• APOB48 lacks the CTD LDL receptor binding site
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mRNA Processing: RNA editingHuman intestines edit APOB mRNA C -> U to create a stop codon @ aa 2153 (APOB48) cf full-length APOB100• APOB48 lacks the CTD LDL receptor binding site• Liver makes APOB100 -> correlates with heart disease
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mRNA Processing: RNA editingTwo types: C->U and A->I• Adenosine de-aminases (ADA) are ubiquitously expressed in mammals• act on dsRNA & convert A to I (read as G)
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mRNA Processing: RNA editingTwo types: C->U and A->I• Adenosine de-aminases (ADA) are ubiquitously expressed in mammals• act on dsRNA & convert A to I (read as G)• misregulation of A-to-I RNA editing has been implicated in epilepsy, amyotrophic lateral sclerosis & depression
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mRNA Processing: Polyadenylation
Addition of 200- 250 As to end of mRNA
Why bother?
• helps identify as mRNA
• required for translation
• way to measure age of mRNA
->mRNA s with < 200 As have short half-life
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mRNA Processing: PolyadenylationAddition of 200- 250 As to end of mRNAWhy bother?• helps identify as mRNA• required for translation• way to measure age of mRNA
->mRNA s with < 200 As have short half-life>50% of human mRNAs have alternative polyA sites!
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mRNA Processing: Polyadenylation>50% of human mRNAs have alternative polyA sites!
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mRNA Processing: Polyadenylation>50% of human mRNAs have alternative polyA sites!• result : different mRNA, can result in altered export, stability or different proteins
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mRNA Processing: Polyadenylation>50% of human mRNAs have alternative polyA sites!• result : different mRNA, can result in altered export, stability or different proteins• some thalassemias are due to mis-poly A
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mRNA Processing: Polyadenylationsome thalassemias are due to mis-poly AInfluenza shuts down nuclear genes by preventing poly-Adenylation (viral protein binds CPSF)
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mRNA Processing: Polyadenylation
1) CPSF (Cleavage and Polyadenylation Specificity Factor) binds AAUAAA in hnRNA
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mRNA Processing: Polyadenylation1) CPSF binds AAUAAA in hnRNA2) CStF (Cleavage Stimulatory Factor) binds G/U rich sequence 50 bases downstream
CFI, CFII bind in between
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Polyadenylation1) CPSF binds AAUAAA in hnRNA2) CStF binds; CFI, CFII bind in between3) PAP (PolyA polymerase) binds & cleaves 10-35 b 3’ to AAUAAA
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mRNA Processing: Polyadenylation3) PAP (PolyA polymerase) binds & cleaves 10-35 b 3’ to AAUAAA4) PAP adds As slowly, CFI, CFII and CPSF fall off
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mRNA Processing: Polyadenylation4) PAP adds As slowly, CFI, CFII and CPSF fall off5) PABII binds, add As rapidly until 250
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Coordination of mRNA processingSplicing and polyadenylation factors bind CTD of RNA Pol II-> mechanism to coordinate the three processes
Capping, Splicing and Polyadenylation all start before transcription is done!
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Export from NucleusOccurs through nuclear poresanything > 40 kDa needs exportinproteinbound to 5’ cap
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Export from Nucleus
In cytoplasm nuclear proteins fall off, new proteins bind• eIF4E/eIF-4F bind cap• also new
proteins bind
polyA tail• mRNA is
ready to be
translated!